MAX5079EUD+TG48

Click here for production status of specific part numbers. MAX5079 General Description The MAX5079 ORing MOSFET controller replaces ORing diodes in high-reliability redundant, parallel-connected power supplies. Despite their low forward-voltage drop, ORing Schottky diodes cause excessive power dissipation at high currents. The MAX5079 allows for the use of low-on-resistance n-channel power MOSFETs to replace the Schottky diodes. This results in low power dissipation, smaller size, and elimination of heatsinks in high-power applications. The MAX5079 operates from 2.75V to 13.2V and includes a charge pump to drive the high-side n-channel MOSFET. Operation down to 1V is possible if an auxiliary voltage of at least 2.75V is available. When the controller detects a positive voltage difference between IN and BUS, the n-channel MOSFET is turned on. The MOSFET is turned off as soon as the MAX5079 sees a negative potential at IN with respect to the BUS voltage, and is automatically turned back on when the positive potential is restored. Under fault conditions, the ORing MOSFET’s gate is pulled down with a 1A current, providing an ultra-fast 200ns turn-off. The reverse voltage turn-off threshold is externally adjustable to avoid unintentional turn-off of the ORing MOSFET due to glitches at IN or BUS caused by hot plugging the power supply. ORing MOSFET Controller with Ultra-Fast 200ns Turn-Off Benefits and Features ●● Drives External MOSFETs Reducing Power Dissipation and Board Space • 2.75V to 13.2V Input ORing Voltage • 1V to 13.2V Input ORing Voltage with 2.75V AuxiliaryVoltage • 14-Pin TSSOP Package ●● Protection Features Increase System Reliability • 2A MOSFET Gate Pulldown Current During Fault Condition • Ultra-Fast 200ns, MOSFET Turn-Off During Fault Condition • Supply Undervoltage and Bus Overvoltage Detection • Power-Good (PGOOD) and Overvoltage (OVP) Outputs for Fault Detection Typical Operating Circuit SUB 75N 03-04 VOUT1 POWER SUPPLY 1 (PS1) ●● ●● ●● ●● ●● ●● Paralleled DC-DC Converter Modules N+1 Redundant Power Systems Servers Base-Station Line Cards RAID Networking Line Cards Ordering Information appears at end of data sheet. 19-3584; Rev 3; 5/18 VBUS N1 BUS COMMON VIN >2.75V Additional features include an OVP flag to facilitate shutdown of a failed power supply due to an overvoltage condition, and a PGOOD signal that indicates if VIN is either below the undervoltage lockout or VBUS is in an overvoltage condition. The MAX5079 operates over the -40°C to +85°C temperature range and is available in a space-saving 14-pin TSSOP package. Applications 1V TO 13.2V IN GATE AUXIN U1 UVLO MAX5079 BUS PGOOD OVI OVP STH RSTH CSTH C+ C- FTH GND RFTH CEXT SUB 75N 03-04 VOUT2 1V TO 13.2V POWER SUPPLY 2 (PS2) VBUS N2 VIN >2.75V IN GATE AUXIN U2 UVLO MAX5079 CSTH C+ CEXT OVI OVP STH RSTH BUS PGOOD C- FTH GND RFTH CBUS MAX5079 ORing MOSFET Controller with Ultra-Fast 200ns Turn-Off Absolute Maximum Ratings GATE to GND..............................................-0.3V to (VIN + 8.5V) All Other Pins to GND............................................-0.3V to +15V Continuous Current Into Any Pin.......................................±50mA Continuous Power Dissipation (TA = +70°C) 14-Pin TSSOP (derate 9.1mW/°C above +70°C)......727.3mW Operating Temperature Range............................ -40°C to +85°C Junction Temperature.......................................................+150°C Storage Temperature Range............................. -65°C to +150°C Lead Temperature (soldering, 10s).................................. +300°C Stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. These are stress ratings only, and functional operation of the device at these or any other conditions beyond those indicated in the operational sections of the specifications is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. Package Information PACKAGE TYPE: 14-PIN TSSOP Package Code U14+2 Outline Number 21-0066 Land Pattern 90-0113 For the latest package outline information and land patterns (footprints), go to www.maximintegrated.com/packages. Note that a “+”, “#”, or “-” in the package code indicates RoHS status only. Package drawings may show a different suffix character, but the drawing pertains to the package regardless of RoHS status. Electrical Characteristics ((VIN = 2.75V to 13.2V and VAUXIN = 0V) or (VIN = 1V and VAUXIN = 2.75V to 13.2V), RSTH = open, RFTH = 0, VUVLO = 1V, VOVI = 0V, TA = -40°C to +85°C, unless otherwise noted. Typical values are at VIN = 12V and TA = +25°C. See the Typical Operating Circuit.) (Note 1) PARAMETER SYMBOL CONDITIONS MIN TYP MAX UNITS POWER SUPPLIES IN Input Voltage Range AUXIN Input Voltage Range (VAUXIN - VIN) High Threshold (When GATE Connects Directly to AUXIN) (Note 2) (VAUXIN - VIN) Hysteresis (When GATE Connects Directly To AUXIN) IN Supply Current AUXIN Leakage Current VIN VAUXIN VAUXIN_ THRESHOLD IIN ILEAK_AUX IAUXIN BUS Leakage Current ILEAK_BUS www.maximintegrated.com VAUXIN rising, IGATE = 10µA VAUXIN_ HYSTERESIS AUXIN Supply Current BUS Supply Current VAUXIN ≥ 2.75V IBUS 2.75 13.20 1.0 13.2 0 13.2 V 5.7 V 4.2 4.9 40 V mV VUVLO = 1V, VIN > VBUS 4 mA VAUXIN = 0 20 µA VUVLO = 1V, VAUXIN = VIN, = 3V; VIN > VBUS 4 mA VIN = 13.2V, VBUS = 0 1 mA VBUS = 13.2V, VBUS > VIN, VBUS > VAUXIN 3 mA Maxim Integrated │  2 MAX5079 ORing MOSFET Controller with Ultra-Fast 200ns Turn-Off Electrical Characteristics (continued) ((VIN = 2.75V to 13.2V and VAUXIN = 0V) or (VIN = 1V and VAUXIN = 2.75V to 13.2V), RSTH = open, RFTH = 0, VUVLO = 1V, VOVI = 0V, TA = -40°C to +85°C, unless otherwise noted. Typical values are at VIN = 12V and TA = +25°C. See the Typical Operating Circuit.) (Note 1) PARAMETER SYMBOL CONDITIONS MIN TYP MAX UNITS IN TO AUXIN SWITCHOVER Switchover High Threshold VAUXIN_HIGH (VIN - VAUXIN), VAUXIN falling -60 +25 +200 mV Switchover Low Threshold VAUXIN_LOW (VIN - VAUXIN), VAUXIN rising -200 -25 +50 mV 2.0 2.25 2.5 V IN UNDERVOLTAGE LOCKOUT Internal UVLO High Threshold VINTUVLO_HIGH VIN rising, VAUXIN = 0 or VAUXIN rising, VIN = 1V, VBUS = 2.75V Internal UVLO Hysteresis VINTUVLO_HYST VIN falling, VAUXIN = 0 or VAUXIN falling, VIN = 1V External UVLO Threshold VUVLO External UVLO Hysteresis VUVLO_HYST External UVLO Input Bias IUVLO VUVLO falling 30 0.568 0.6 mV 0.632 60 V mV 500 nA 10 25 µs 12.5 20 mV ORing MOSFET CONTROL ORing MOSFET Turn-On Time tON ORing MOSFET Forward Voltage Threshold (Fast Comparator) VDTH ORing MOSFET Reverse Voltage Turn-Off Threshold (Fast Comparator (VIN - VBUS)) VFTH ORing MOSFET Reverse Voltage Blanking Time (Fast Comparator) tFBL Slow-Comparator Output Voltage Threshold on STH VO_STH ORing MOSFET Reverse Voltage Turn-Off Threshold (Slow Comparator (VIN - VBUS)) VSTH (VIN - VBUS) to ISTH Transconductance (Slow Comparator) ORing MOSFET Reverse Voltage Blanking Time (Slow Comparator) www.maximintegrated.com GM_STH CGATE = 10nF, CEXT = 100nF, MOSFET gate threshold = 2V (VIN - VBUS) rising, VAUXIN ≥ 2.75V RFTH = 0 RFTH = 12kΩ RFTH = 27kΩ, VIN ≥ 3.5V -12 -24 -31 -63 -104 -150 -126 -204 -300 VBUS = 2.8V, RFTH = 0, VBUS - VIN = 0.3V 50 0.95 1 1.05 RSTH open -0.1 -12 -24.0 RSTH = 500kΩ -25 RSTH = 64kΩ -100 VSTH = 0V 0.17 CSTH = 0.047µF CSTH = 0.22µF 0.5 0.9 5 mV ns VIN ≥ 2.75V STH floating tSBL VAUXIN ≥ 2.75V 5 V mV mS 1.5 ms 14 Maxim Integrated │  3 MAX5079 ORing MOSFET Controller with Ultra-Fast 200ns Turn-Off Electrical Characteristics (continued) ((VIN = 2.75V to 13.2V and VAUXIN = 0V) or (VIN = 1V and VAUXIN = 2.75V to 13.2V), RSTH = open, RFTH = 0, VUVLO = 1V, VOVI = 0V, TA = -40°C to +85°C, unless otherwise noted. Typical values are at VIN = 12V and TA = +25°C. See the Typical Operating Circuit.) (Note 1) PARAMETER SYMBOL CONDITIONS MIN TYP CEXT = 100nF, VIN ≥ 2.75V 0.7 2 VGATE = VIN, VIN = 5.1V, VBUS = 5V; VOUT = 1V 0.9 2 MAX UNITS ORing MOSFET DRIVER Gate-Charge Current Gate Discharge Current (Note 3) IGATE IGATE.DIS_MIN VGATE ≥ VIN, VIN = 2.75V, VBUS = 3.5V 1.3 VBUS = 3.5V, CGATE = 0.1µF 600 VBUS = 3.5V, CGATE = 0.01µF 200 tDIS_GATE VBUS = 3.5V 70 RGATE_IN (VGATE - VIN) = 100mV; VIN ≥ 2.75V VGATE ≥ VIN, VIN = 12V, VBUS = 13.2V Gate Fall Time Gate Discharge Current Delay Time (Time from VIN Falling from 3.7V to 3V to VGATE = VIN) Gate to IN Resistance Gate to IN Clamp Voltage tFGATE VGATE_IN_CLAMP IGATE = 10mA, VIN ≥ VBUS Gate-Drive Voltage (Measured with Respect to VIN) (VGATE - VIN) VIN Switchover Threshold to Higher GATE Voltage (Note 4) VIN_SOTH+ VIN Switchover Hysteresis (Note 4) VIN_SOHYS Charge-Pump Frequency fCP PROTECTION OVI Input Bias Current OVI Threshold OVP Output Low Voltage OVP Leakage Current PGOOD Leakage Current PGOOD Output Low Voltage IOVI VOVI_TH VOVP_LOW IOVP_LEAK IPG_LEAK VPG_LOW mA 6.8 A 3.2 8.5 ns 200 ns 900 Ω 11 V V 2.7V < VIN < 13.2V 3.8 6.5 7 7.7 VIN = 2.75V 4.5 5 5.5 7.4 8 8.5 VIN = 13.2V 40 External OVI rising VOVI = 1V, ISINK = 10mA ISINK = 2mA kHz 1100 0.568 500 nA 0.6 0.632 V 0.2 0.4 V 1 µA 1 µA 0.4 V VIN = 2.75V, VOVP = 13.2V VPGOOD = 13.2V mV 70 Internal, VIN < 5V, VAUXIN < 5V V 0.2 Note 1: All devices are production tested at +25°C. Limits over temperature are guaranteed by design. Note 2: Threshold is reached when charge pump turns off. Note 3: Gate discharge current is guaranteed through the testing of gate fall time. Note 4: VIN switchover threshold is VIN at which the gate-drive voltage (VGATE - VIN) goes from 5V to 7V, VIN rising and (VIN ≥ VBUS). www.maximintegrated.com Maxim Integrated │  4 MAX5079 ORing MOSFET Controller with Ultra-Fast 200ns Turn-Off Typical Operating Characteristics (TA = +25°C, unless otherwise noted. See the Typical Operating Circuit.) 2.0 1.5 1.0 0.5 0 -40 -25 -10 5 20 35 50 65 80 95 110 125 TA = +125°C 0.02 60 VFTH (V) tSTH (ms) 70 50 40 30 20 10 78 76 fCP (kHz) 74 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 1.0 TA = +125°C TA = +25°C 66 TA = -40°C 64 62 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 VIN (V) www.maximintegrated.com 80 72 64 FAST-COMPARATOR RESPONSE TIME VIN = 1V, VAUXIN = 5V VIN = 5V, VAUXIN = 0V 48 40 VIN = 12V, VAUXIN = 0V 32 16 VIN = 2.75V, VAUXIN = 12V 8 0 6.0 5.5 20 40 60 80 100 120 0 140 -40 -25 -10 5 20 35 50 65 80 95 110 125 TEMPERATURE (°C) FAULT CURRENT WAVEFORM (IN SHORTED TO PGND) VIN = 12V 5.0 MAX5079 toc09 MOSFET REVERSE CURRENT 5A/div 4.5 4.0 BUS 5V/div 3.5 3.0 2.5 GATE 10V/div 2.0 1.5 1.0 0.5 0 1000 56 24 TA = -40°C GATE-CHARGE CURRENT vs. CEXT 70 60 TA = +85°C CHARGE-PUMP FREQUENCY vs. INPUT VOLTAGE 72 68 1.5 1.4 1.3 1.2 1.1 1.0 0.9 0.8 0.7 0.6 0.5 0.4 0.3 0.2 0.1 0 FAST-COMPARATOR REVERSE VOLTAGE THRESHOLD (VFTH vs. RFTH) RFTH (kΩ) TA = +125°C TA = +85°C 100 10 RSTH (kΩ) CSTH (µF) GATE-CHARGE CURRENT (mA) 80 0 MAX5079 toc07 0 0 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 MAX5079 toc05 80 0.08 0.06 tRESPONSE (ns) SLOW-COMPARATOR BLANKING TIME tSTH vs. CSTH (RSTH = 180kΩ) 75mV OVERDRIVE 0.10 VIN (V) MAX5079 toc04 90 0.12 0.04 TEMPERATURE (°C) 100 VSTH (V) TA = +85°C MAX5079 toc06 VAUXIN = 2.7V 0.16 0.14 TA = -40°C 3.5 3.0 2.5 TA = -40°C, TA = +25°C, TA = +85°C, TA = +125°C 0.18 TA = +25°C 4.0 1 0 MAX5079 toc02 4.5 2 0.20 MAX5079 toc08 VAUXIN = 5V IGATE (mA) IAUXIN (mA) VAUXIN = 10V 6.0 5.5 5.0 MAX5079 toc01 3 SLOW-COMPARATOR REVERSE VOLTAGE THRESHOLD (VSTH vs. RSTH) GATE-CHARGE CURRENT vs. VIN MAX5079 toc03 AUXIN SUPPLY CURRENT vs. TEMPERATURE (VIN = VBUS = 1V) IN 5V/div 1 10 CEXT (nF) 100 400ns/div VIN = 5V, VBUS = 5V, VAUXIN = 0V, CSTH = 0, RSTH = OPEN, RFTH = 0, UVLO = IN Maxim Integrated │  5 MAX5079 ORing MOSFET Controller with Ultra-Fast 200ns Turn-Off Typical Operating Characteristics (continued) (TA = +25°C, unless otherwise noted. See the Typical Operating Circuit.) FAULT CURRENT WAVEFORM (IN SHORTED TO PGND) FAULT CURRENT WAVEFORM (IN SHORTED TO PGND) MAX5079 toc10 MAX5079 toc11 MOSFET REVERSE CURRENT 10A/div MOSFET REVERSE CURRENT 10A/div BUS 2V/div BUS 10V/div GATE 5V/div GATE 20V/div IN 2V/div IN 10V/div 1µs/div VIN = 2.75V, VBUS = 2.75V, VAUXIN = 0V, CSTH = 0µF, RSTH = OPEN, RFTH = 0, UVLO = IN 400ns/div VIN = 12V, VBUS = 12V, VAUXIN = 0V, CSTH = 0µF, RSTH = OPEN, RFTH = 0, UVLO = IN FAULT CURRENT WAVEFORM (IN SHORTED TO PGND) FAULT CURRENT WAVEFORM (IN SHORTED TO PGND) MAX5079 toc12 MAX5079 toc13 MOSFET REVERSE CURRENT 10A/div MOSFET REVERSE CURRENT 10A/div BUS 1V/div BUS 5V/div GATE 5V/div GATE 10V/div IN 1V/div 1µs/div VIN = 1V, VBUS = 1V, VAUXIN = 5V, CSTH = 0µF, RSTH = OPEN, RFTH = 0, UVLO = IN www.maximintegrated.com IN 5V/div 1µs/div VIN = 5V, VBUS = 5V, VAUXIN = 5V, CSTH = 0µF, RSTH = OPEN, RFTH = 0, UVLO = IN Maxim Integrated │  6 MAX5079 ORing MOSFET Controller with Ultra-Fast 200ns Turn-Off Typical Operating Characteristics (continued) (TA = +25°C, unless otherwise noted. See the Typical Operating Circuit.) FAULT CURRENT WAVEFORM (IN SHORTED TO PGND) POWER-UP WAVEFORM MAX5079 toc15 MAX5079 toc14 MOSFET REVERSE CURRENT 10A/div IN 2V/div BUS 10V/div BUS 2V/div GATE 20V/div GATE 10V/div IN 10V/div CXN 10V/div 40µs/div VIN = 5.2V, VBUS = 4.9V, IBUS = 5A 1µs/div VIN = 12V, VBUS = 12V, VAUXIN = 5V, CSTH = 0, RSTH = OPEN, RFTH = 0, UVLO = IN POWER-UP WAVEFORM POWER-UP WAVEFORM MAX5079 toc16 MAX5079 toc17 IN 5V/div IN 1V/div BUS 5V/div BUS 500mV/div GATE 10V/div GATE 5V/div CXN 10V/div CXN 10V/div 20µs/div VIN = 12.2V, VBUS = 11.9V, IBUS = 5A www.maximintegrated.com 20µs/div VIN = 1.2V, VBUS = 1V, VAUXIN = 5V, IBUS = 5A Maxim Integrated │  7 MAX5079 ORing MOSFET Controller with Ultra-Fast 200ns Turn-Off Pin Configuration TOP VIEW CXN 1 14 AUXIN CXP 2 13 IN OVP 3 PGOOD 4 MAX5079 12 GND 11 BUS STH 5 10 GATE FTH 6 9 PGND OVI 7 8 UVLO TSSOP Pin Description PIN NAME 1 CXN Negative Terminal of External Flying Charge-Pump Capacitor FUNCTION 2 CXP Positive Terminal of External Flying Charge-Pump Capacitor 3 OVP Open-Drain Active-Low Output. OVP sinks up to 10mA when VOVI ≥ 0.6V and VIN ≥ VBUS. OVP can be used to drive an optodiode. Cycle power or pull UVLO low and then high to reset OVP. 4 PGOOD 5 STH ORing MOSFET Slow-Comparator Reverse Voltage Threshold and Blanking Time Setting Input. Connect a resistor from STH to GND to set the threshold. Connect a capacitor from STH to GND to set the blanking time. Leave STH floating to set the internal threshold (-12mV) and internal blanking time (0.9ms). 6 FTH Fast-Comparator Reverse Threshold Setting. Connect a resistor from FTH to GND to set the fastcomparator reverse voltage threshold from -24mV to -400mV. 7 OVI Overvoltage Comparator Input. Connect OVI to BUS through a resistive divider. 8 UVLO Undervoltage Lockout Comparator Input. Connect UVLO to IN through a resistive divider. The MAX5079 remains off until VUVLO rises above 0.66V. When VUVLO rises above 0.664V, VGATE is raised to VIN. Open-Drain Active-Low Output. PGOOD pulls low when VUVLO ≤ 0.6V or VOVI ≥ 0.6V. 9 PGND Power Ground. Ground discharge path of the 2A GATE pulldown. Connect to external power ground plane. 10 GATE Gate-Driver Output for n-Channel ORing MOSFET 11 BUS Bus Voltage-Sense Input. Connect BUS to the drain of the ORing MOSFET to sense the polarity of the Bus Current. The MAX5079 receives its power from BUS when VIN and VAUXIN are not present. 12 GND Signal Ground. Connect to the low-level signal or analog ground. 13 IN 14 AUXIN Source Connection for ORing MOSFET and Supply Input for the MAX5079. Connect IN directly to the power-supply voltage of 2.75V to 13.2V or 1V to 13.2V with VAUXIN ≥ 2.75V. Auxiliary Power-Supply Input. AUXIN supplies power to the IC when 1V ≤ VIN ≤ 2.75V. Connect AUXIN to 2.75V or higher if VIN is less than 2.75V. www.maximintegrated.com Maxim Integrated │  8 MAX5079 ORing MOSFET Controller with Ultra-Fast 200ns Turn-Off Block Diagram CXP CXN GATE IN BUS VSUPPLY AUXIN TO GATE DIRECT CONNECTION VSUPPLY GM BUS IN/AUXIN/BUS SWITCHOVER AUXIN IN STH VSUPPLY VSUPPLY CPOFF 0.6V REFERENCE INTERNAL UVLO GND VSUPPLY UVLO PGOOD OVI PULLDOWN REG DRIVER 2A PULLDOWN N MAX5079 PGOOD LOGIC OV LOGIC OVP www.maximintegrated.com FTH TOP LOGIC GATE TARGET SELECTOR COMPARATOR OVI 0.9ms DELAY VSUPPLY IN/AUXIN SUPPLY SWITCHOVER UVLO 20µA CHARGE PUMP IN/AUXIN CHARGE-PUMP SWITCHOVER HYSTERESIS CONTROL PGOOD PGND Maxim Integrated │  9 MAX5079 Detailed Description The MAX5079 ORing MOSFET controller drives an external n-channel MOSFET and replaces ORing diodes in high-reliability redundant power-management systems or multiple paralleled power supplies. The device has an internal charge pump to drive the high-side n-channel ORing MOSFET. Additional features include an adjustable undervoltage lockout threshold (UVLO), output overvoltage detector (OVI/OVP), input power-good detector (PGOOD), and two programmable reverse voltage detectors to detect both fast and slow rises in the reverse voltage across the ORing MOSFET. The input powersupply range is from 2.75V to 13.2V or down to 1V when an auxiliary supply of at least 2.75V is available. Operational Description This section describes a detailed startup sequence and behavior of the MAX5079 under different conditions of VBUS and VIN. The MAX5079 powers up whenever VIN is equal to or greater than 2.75V and VUVLO exceeds the UVLO threshold of 0.66V. Operation with VIN down to 1V is possible as long as VUVLO ≥ 0.6V and VAUXIN ≥ 2.75V. When VUVLO crosses the UVLO threshold, VGATE rises to VIN and the charge pump turns on. The charge pump delivers 2mA to charge the gate capacitance of the external MOSFET connected to GATE. The constant gate-charge current prevents large inrush currents from the input supply. During turn-on, the MAX5079 will ignore the reverse voltage at IN with respect to BUS. This is necessary to avoid the unintentional turn-off of the ORing MOSFET as the momentary inrush current causes VIN to dip. The Figure 1 shows the MAX5079 in an ORing configuration with three parallel power supplies (PS1, PS2, and PS3) and three MAX5079s (U1, U2, and U3) provided by outputs VOUT1, VOUT2, and VOUT3. The following events must be carefully considered to ensure proper functionality of the MAX5079 ICs. 1) VBUS is zero with a discharged capacitor (CBUS). All three power supplies are turned ON simultaneously. VOUT1 comes up before VOUT2 and VOUT3. a. When VOUT1 turns on, the bus capacitors (CBUS) begin charging from VOUT1 through N1’s body diode. When VUVLO (U1) rises above the UVLO threshold, the MAX5079 (U1) charge pump turns on, and U1 monitors the positive potential from VOUT1 to VBUS. When VOUT1 ≥ VBUS the charge pump brings GATE (U1) to 5.5V above VIN (U1) (or 7.5V above VIN depending on the magnitude of VIN), by sourcing 2mA into N1’s gate capacitance. This results in a less than 10μs turn-on time for www.maximintegrated.com ORing MOSFET Controller with Ultra-Fast 200ns Turn-Off the FDB7045L used in the MAX5079 evaluation kit. The fast turn-on is needed to assure that N1 is ON before the rising VOUT1 reaches its steadystate value. If the MOSFET is not turned on before VOUT1 reaches its steady state, VBUS may overshoot due to the shorting of the 0.7V (forward drop) of N1’s body diode. A higher VIN (U1) can more quickly charge the charge-pump capacitor to 5V (or 7V), while a lower VIN (U1) will take longer. Typically the MOSFET turns on at VGS = 2.5V. Ensure that the soft-start time of the power supply is large enough (> 5ms) to avoid VOUT1 racing ahead and causing VBUS to overshoot. Care must be taken to avoid the overloading of VOUT1 by either limiting the source current (using the current-sharing circuit) or delay the loading of the BUS until all three power supplies are up and running. b. VOUT2 turns on and begins increasing the voltage at IN (U2). VUVLO (U2) crosses the UVLO threshold, the MAX5079 (U2) charge pump turns on and U2 monitors the VOUT2 to VBUS voltage. When this voltage difference becomes positive, GATE (U2) begins sourcing 2mA into N2’s gate capacitance. During turn-on, the reverse voltage turn-off circuit is momentarily disabled. If VOUT2 is lower than VOUT1, the external load-sharing controller circuit of PS2 will try to increase VOUT2 to source current from VOUT2. Assume VOUT2’s rise time is slow enough not to cause any overshoot before N2 turns on and starts sharing the current. c. VOUT3 turns on and U3 follows the same sequence as U2. Eventually VOUT1, VOUT2, and VOUT3 reach to equilibrium and sharing equal currents. 2) PS1 and PS2 are on and sharing the load when PS3 is hot-inserted. PS3 will take the same course as discussed in 1b above. a. If VOUT3 is higher than VBUS, the BUS voltage will increase to the new level determined by VOUT3. The external load-sharing controller circuit of PS1 and PS2 will increase VOUT1 and VOUT2 to force current sharing. b. If VOUT3 is lower than VBUS, the load-sharing circuit of PS3 will increase VOUT3 to force the sharing of current. This causes VOUT3 to increases above VBUS. When this voltage difference becomes positive, GATE (U3) begins sourcing 2mA into N3’s gate capacitance. Again, the reverse voltage turnoff circuit is disabled momentarily, as discussed before. The load-sharing circuit of PS3’s controller will adjust VOUT3 so as to share the load current. Maxim Integrated │  10 MAX5079 c. During the hot insertion, a voltage spike can occur at N1 and N2 and cause the (VOUT1 to VBUS) or (VOUT2 to VBUS) voltage to go negative. If the reverse voltage is below the fast-comparator reverse voltage threshold (VFTH) but above the programmed slow-comparator reverse voltage threshold (VSTH), the spike is ignored for the programmed blanking time (tSTH). If the spike is longer than 50ns (the fast-comparator internal blanking time, tFBL) and larger than VFTH, then U1 and U2 will turn off N1 and N2 quickly. If the magnitude of the voltage spike is above VSTH but less than VFTH, and longer than the slow-comparator blanking time (tSTH), U1 and U2 will turn off their respective ORing MOSFETs (N1 and N2) by discharging their GATE pins to PGND. The external load-sharing circuit of PS1 and PS2 will force VOUT1, VOUT2 above VBUS and N1, N2 will turn back on through the 2mA current sourcing from the GATE pins of U1 and U2. To avoid this situation the user can set the slow-comparator threshold and blanking time depending on the magnitude and duration of the voltage spikes. d. PS3 fails to start. VUVLO (U3) threshold is not crossed and U3 keeps N3 off. e. PS3 goes into an overvoltage condition (no feedback). This causes VBUS to go into an overvoltage condition increasing the loading on PS3 (provided PS3 is able to supply all the required BUS current). The current-sharing circuit will force the outputs of PS1 and PS2 to increase and eventually saturate at their current-sharing voltage range. Eventually only PS3 will have a positive voltage at IN (U3) with respect to BUS. PS1 and PS2 will have a negative voltage at VOUT1 and VOUT2 with respect to BUS. All overvoltage inputs OVI (U1), OVI (U2), and OVI (U3) sense the overvoltage, but only OVP (U3) is asserted and latched low. GATE (U3) is pulled to PGND and remains low as long as VOVI ≥ 0.6V. When VOVI drops below 0.6V, OVP remains low. However, U3 tries to turn on N3 unless VOUT3 is actively kept below the undervoltage lockout. Use OVP (U3) to either drive the cathode of the optocoupler to shutdown PS3 from the primary side or use OVP (U3) to fire an SCR connected between VOUT3 and PGND. 3) PS1, PS2, PS3 are turned on with a shorted BUS. Body diodes of N1, N2, and N3 conduct and short the outputs of PS1, PS2, and PS3 to PGND. The power supplies go into current limit (either in foldback or in hiccup mode). www.maximintegrated.com ORing MOSFET Controller with Ultra-Fast 200ns Turn-Off The MAX5079s remain in undervoltage lockout and keep all ORing MOSFETs off. The average current sourced by PS1, PS2, or PS3 must be low enough so as not to exceed the MOSFETs power dissipation (PD = VF x ISHORT). a. Use additional n-channel MOSFETs in series with N1, N2, and N3 in the reverse direction to isolate the power supplies from a shorted bus (Figure 2). When power is turned on with a shorted bus, VIN_ (U1, U2, U3) increases and VUVLO rises above the UVLO threshold. The MAX5079’s GATE outputs start charging the back-to-back ORing MOSFET gates. The short-circuit condition at BUS collapses VIN (U1), VIN (U2), and VIN (U3) sending the MAX5079s into undervoltage lockout. This turns off the MAX5079s entirely, including discharging of the charge-pump storage capacitors. The IN voltages come back up again crossing UVLO (UVLO has 60mV hysteresis). A new cycle starts and the time required to charge the chargepump capacitor and the turn-on time of the device serves as a dead time. However, the dead time may not be enough to reduce the dissipation in the MOSFETs to an acceptable level. We advise in keeping the short-circuit current low and providing hiccup current-limit protection to the power supplies (PS1, PS2, and PS3). b. Any other overload condition that would sustain the IN voltage above UVLO, will keep the MOSFETs ON continuously. Ensure the MOSFETs’ current rating is higher than the maximum short-circuit source current of the power supplies (PS1, PS2, and PS3) to avoid damage to the ORing MOSFETs. 4) PS1, PS2, and PS3 are present and PS1 is shorted to GND. VOUT1 drops below VBUS. The negative potential from VIN (U1) to VBUS increases above the fast-comparator threshold and lasts longer than the 50ns blanking time. The MAX5079 (U1) takes its power from the voltage at BUS (U1). Connect BUS close to CBUS, away from N1 so that U1 can receive power from BUS for a few microseconds until N1 isolates BUS from IN. N1 is discharged with 2A pulldown current, turning off N1 and isolating PS1 from the BUS. The load-sharing circuit of PS2 and PS3 will increase PS2 and PS3’s load current until the total bus current requirement is satisfied. For VIN (U1) < 2.75V, VAUXIN (U1) must come from an independent source or remain on for some time (a few microseconds) after VIN (U1) has failed. This minimum on-time is needed to discharge the gate of the ORing MOSFET and isolate PS1 from the BUS. Maxim Integrated │  11 MAX5079 5) PS1, PS2, PS3 are present and PS1 goes open. PS1’s output capacitors discharge and VOUT1 drops below VBUS. The MAX5079 (U1) senses a negative potential from VOUT1 to VBUS. Depending upon how fast PS1’s output capacitor discharges, N1 is turned off due to the crossing of the fast- or slow-comparator reverse voltage threshold. N1’s gate is discharged with a 2A sink current into GATE (U1), turning off N1 and isolating PS1 from the BUS. The load-sharing circuit of PS2 and PS3 will increase PS2 and PS3’s load current until the total BUS current requirement is satisfied. 6) PS1, PS2, PS3 are present and providing BUS current. PS1 loses its feedback signal and goes into an overvoltage condition. VBUS increases and PS1 is loaded heavily. The current share circuit forces VOUT2 and VOUT3 higher and they will eventually saturate at their current-sharing voltage range. Now only PS1 has a positive voltage at IN (U1) with respect to BUS. All OVI inputs will sense the overvoltage, but only OVP (U1) will be asserted and latched low. GATE (U1) is pulled to PGND and remains low as long as VOVI ≥ 0.6V. When VOVI drops below 0.6V, OVP remains low, however, U1 tries to turn on N1 unless VOUT1 is actively kept below the undervoltage lockout. Use OVP (U1) to either drive the cathode of an optocoupler to shutdown PS1 from the primary, or fire an SCR connected between IN (U1) and PGND. Internal and External Undervoltage Lockout The internal undervoltage lockout monitors VIN and VAUXIN and keeps the MAX5079 off until either voltage reaches 2.75V. Once powered and VIN and/or VAUXIN increase above 2.75V, the external UVLO is monitored. The external undervoltage lockout feature monitors the UVLO input and keeps the MAX5079 off (GATE shorted to PGND) until VUVLO is greater than 0.66V. Connect a resistive divider from IN to UVLO to GND or from AUXIN to UVLO to GND to set the external undervoltage lockout threshold. We advise setting the external UVLO ≥ 2.75V when AUXIN is not present. Charge Pump The MAX5079 has an internal charge pump that pumps the gate-drive voltage (VGATE) high enough to fully enhance the n-channel ORing MOSFET. The charge pump is divided into two stages, a voltage doubler running at 70kHz using an external charge-pump capacitor www.maximintegrated.com ORing MOSFET Controller with Ultra-Fast 200ns Turn-Off (CEXT), and a voltage tripler running at 1MHz using an internal capacitor. Connect an external capacitor (CEXT) between C+ and C-. CEXT is charged from the higher of VIN or VAUXIN. When the rising VIN becomes greater then VBUS (VUVLO > 0.66V), CEXT is discharged through GATE into the external MOSFET’s gate capacitance. The charge-pump output is controlled by an internal regulator. The chargepump output at GATE sources typically 2mA. This provides enough current drive to turn on a typical ORing MOSFET in less than 10μs. When (VGATE - VIN) reaches the target value (depending on VIN) the charge pump is switched off (see the Electrical Characteristics table). Choose CEXT equal to 10 times the ORing MOSFET gate capacitance. Too low of a capacitance will delay the turnon of the ORing MOSFET, while too high of a capacitance can cause excessive ripple at VIN. Bypass IN to GND with a 1μF ceramic capacitor to avoid ripple at IN caused by the charge-pump switching. A clamp is placed internally between GATE and IN to prevent (VGATE - VIN) from exceeding 11V. When VIN is less than 5V, the charge pump (tripler) will increase VGATE to 3x’s VIN to further reduce the RDSON of the ORing MOSFET. The internal charge-pump booster (voltage tripler) section is operational only when VIN and VAUXIN are low and is turned off when VIN exceeds 5V. When an additional supply is connected to AUXIN and (VAUXIN - VIN) > 5V, both charge pumps are completely disabled. In this case, the charging of the ORing gate comes entirely from VAUXIN. In this case, the chargepump flying capacitor can be eliminated and C+, Ccan be left floating. GATE Drive and Gate Pulldown The MAX5079’s charge pump provides bias to charge the ORing MOSFET gate above IN (the MOSFET’s source). GATE source current and the turn-on speed depends upon the value of CEXT (connected between C+ and C-). Typically GATE can source up to 2mA with CEXT = 0.1μF. This enables VGATE to rise to over 2V above VIN in less than 10μs for an ORing MOSFET gate capacitance of up to 10nF. With VIN < 5V, 12V MOSFETs can be used for better RDSON characteristics. The MAX5079 automatically selects the gate-drive voltage for VIN = 5V or VIN = 12V. For VIN ≤ 8V, the gate drive is 5V above VIN and for VIN > 8V, the gate drive is 7V above VIN. Lower gate drive means faster turn-off during faults, while higher gatedrive means lower RDSON. Maxim Integrated │  12 MAX5079 ORing MOSFET Controller with Ultra-Fast 200ns Turn-Off A fast and slow comparator monitor the voltage from IN to BUS. When this voltage crosses the negative fast- or slow-comparator threshold voltage for the blanking time duration, GATE is pulled low by an internal 2A current sink. Both comparators have an adjustable threshold voltage. GATE is pulled low if any of the following conditions are met. 1) VUVLO < 0.6V. 2) VAUXIN < 2.25V and VIN < 2.25V. 3) VOVI ≥ 0.6V. 4) VIN ≤ (VBUS - VFTH) or VIN ≤ (VBUS - VSTH) and (VGATE - VIN) ≥ 1.8V. When the above conditions are not true and VIN ≤ VBUS, GATE is shorted to IN. To insure that the external MOSFET is quickly turned off, given the above conditions, the GATE pulldown circuitry is powered by either VIN, VAUXIN, or VBUS as long as any one is greater then 2.75V. Fast Comparator (FTH) The fast comparator has a 50ns blanking time to avoid unintentional turn-off of the ORing MOSFET during fast transients. Additionally, the fast-comparator reverse voltage threshold (VFTH) is programmable to suit the need of an individual application. Higher VFTH threshold allows for a larger glitch at BUS during a fault, but improves the noise immunity. Lower VFTH reduces glitches at BUS during a fault, however, with lower VFTH spikes at BUS or glitches at IN can be read as faults, unintentionally turning off the ORing MOSFET. Program VFTH by connecting a resistor from FTH to GND. Adjust VFTH to optimize the system performance using the following equation: R FTH = VFTH − 24mV 6.67µA VFTH can be chosen from 24mV to 400mV. Connect FTH to GND to choose the default 24mV threshold. www.maximintegrated.com Slow Comparator (STH) The MAX5079 includes a slow comparator to provide glitch immunity during the hot insertion or removal of paralleled power supplies. During the hot insertion, BUS can see voltage spikes. These spikes can be interpreted as a reverse voltage across the ORing MOSFET. The amplitude of the spikes is proportional to the load step seen by the parallel power supply while the duration of the spikes depends on the loop response of the load share and PWM controller. The slow comparator has a programmable reverse voltage threshold (VSTH) as well as a programmable blanking time (tSTH). An internal transconductance amplifier converts the IN to BUS differential voltage to a current and applies it to a parallel combination of resistor and capacitor (RSTH and CSTH) from STH to GND. The reverse threshold voltage (VSTH) for the slow comparator is adjusted through RSTH. Use the following equation to calculate the RSTH for a required VSTH. R STH = 1V V 12mV − ( STH ) x G M_STH where GM_STH = 0.17mS. The internal 500kΩ resistance from the output of the transconductance to GND can change the actual VSTH if RSTH is above 50kΩ. In this case, see the Typical Operating Circuit to select RSTH. Once RSTH is chosen, the blanking time can be adjusted by CSTH. The delay time is:    VSTH = R STH × C STH × −ln 1 − t STH  + t SBL   VSTH + VOD  where tSBL = 0.9ms and is the default blanking time generated by an internal digital delay. Leaving STH floating results in a 12mV threshold voltage and a 0.9ms blanking time. VOD (overdrive) is the difference between actual reverse voltage (VBUS - VIN) and VSTH threshold. Maxim Integrated │  13 MAX5079 Overvoltage Protection Latch (OVI/OVP) OVI is the negative input to the overvoltage comparator. The positive input of this comparator is connected to the internal 0.6V reference and an open-drain output is provided at OVP. The overvoltage sensing for overvoltage protection is done at either IN or BUS. OVP latches low and the internal GATE pulldown circuitry is activated and pulls GATE low only when both of the conditions are satisfied: 1) VOVI ≥ 0.6V. 2) VIN ≥ VBUS. OVP can sink 10mA maximum. Cycle power or pull UVLO low and then high again to reset the OVP latch. GATE is pulled to PGND and remains low as long as VOVI ≥ 0.6V. When VOVI drops below 0.6V, OVP remains low. However, the MAX5079 tries to turn on the ORing MOSFET unless VIN is actively kept below the undervoltage lockout. Use OVP to drive the cathode of an optocoupler to shut down the respective power supply from the primary side (see Figure 1) or fire an SCR connected from IN to PGND. ORing MOSFET Controller with Ultra-Fast 200ns Turn-Off 1) Place a 1μF ceramic input bypass capacitor physically close to IN and PGND. Connect IN as close as possible to the source of the ORing MOSFET. 2) Sense the VBUS close to the bulk capacitor, away from the drain of the ORing MOSFET. When IN is shorted to ground during a fault, BUS is also pulled low through the ORing MOSFET. In the absence of VAUXIN, the MAX5079 loses both power inputs VIN and VBUS. This can cause a delayed pulldown of the gate. Sensing the BUS away from the ORing MOSFET drain, close to the BUS bulk capacitor provides power to the MAX5079 for a few microseconds, long enough to pull down the ORing MOSFET gate and isolate BUS from a shorted IN. 3) Place the charge-pump capacitor (CEXT) and the slow-comparator blanking time adjustment capacitor (CSTH) as close as possible to the MAX5079. 4) Run a thick trace from the gate of the ORing MOSFET to GATE. Power-Good Comparator (PGOOD) PGOOD output pulls low when VUVLO falls below 0.6V or VOVI goes above 0.6V. PGOOD can sink a maximum of 2mA. Layout Guidelines www.maximintegrated.com Maxim Integrated │  14 MAX5079 ORing MOSFET Controller with Ultra-Fast 200ns Turn-Off Typical Application Circuit VOUT1 POWER SUPPLY 1 (PS1) N1 1V TO 13.2V VIN >2.75V RSTH IN GATE AUXIN U1 UVLO OVP STH MAX5079 C+ OVI PGOOD CSTH GND RFTH N2 1V TO 13.2V VBUS VBUS VIN TO PRIMARY-SIDE SHUTDOWN >2.75V RSTH IN GATE AUXIN U2 UVLO OVP STH MAX5079 C+ BUS CBUS OVI PGOOD C- FTH CSTH GND RFTH CEXT VOUT3 POWER SUPPLY 3 (PS3) BUS C- FTH CEXT POWER SUPPLY 2 (PS2) BUS COMMON VBUS TO PRIMARY-SIDE SHUTDOWN VOUT2 VBUS N3 1V TO 13.2V VBUS VBUS VIN TO PRIMARY-SIDE SHUTDOWN >2.75V RSTH IN GATE AUXIN U3 UVLO OVP STH MAX5079 C+ C- FTH BUS OVI PGOOD GND CSTH CEXT RFTH Figure 1. Typical Application Circuit www.maximintegrated.com Maxim Integrated │  15 MAX5079 ORing MOSFET Controller with Ultra-Fast 200ns Turn-Off Typical Application Circuit (continued) VOUT1 POWER SUPPLY 1 (PS1) 1V TO 13.2V VBUS VBUS VIN TO PRIMARY-SIDE SHUTDOWN >2.75V RSTH IN GATE AUXIN U1 UVLO OVP STH MAX5079 C+ C- FTH CSTH POWER SUPPLY 2 (PS2) BUS OVI PGOOD GND RFTH CEXT VOUT2 BUS COMMON 1V TO 13.2V VBUS VBUS TO PRIMARY-SIDE SHUTDOWN VIN >2.75V RSTH IN GATE AUXIN U2 UVLO OVP STH MAX5079 C+ C- FTH CSTH CEXT BUS CBUS OVI PGOOD GND RFTH Figure 2. Parallel Supplies with Back-to-Back MOSFET www.maximintegrated.com Maxim Integrated │  16 MAX5079 ORing MOSFET Controller with Ultra-Fast 200ns Turn-Off Chip Information Ordering Information PART TEMP RANGE PIN-PACKAGE MAX5079EUD -40°C to +85°C 14 TSSOP www.maximintegrated.com TRANSISTOR COUNT: 2,911 PROCESS: BiCMOS Maxim Integrated │  17 MAX5079 ORing MOSFET Controller with Ultra-Fast 200ns Turn-Off Revision History REVISION NUMBER REVISION DATE 0 2/05 Initial release 1 3/09 Updated Electrical Characteristics table 2, 3 2 4/15 Revised Benefits and Features section 1 Corrected blanking time equation in the Slow Comparator (STH) section; updated tDELAY to tSTH and VDD to VOD 13 Updated Package Information table 2 2.5 3 5/18 PAGES CHANGED DESCRIPTION — For pricing, delivery, and ordering information, please contact Maxim Direct at 1-888-629-4642, or visit Maxim Integrated’s website at www.maximintegrated.com. Maxim Integrated cannot assume responsibility for use of any circuitry other than circuitry entirely embodied in a Maxim Integrated product. No circuit patent licenses are implied. Maxim Integrated reserves the right to change the circuitry and specifications without notice at any time. The parametric values (min and max limits) shown in the Electrical Characteristics table are guaranteed. Other parametric values quoted in this data sheet are provided for guidance. Maxim Integrated and the Maxim Integrated logo are trademarks of Maxim Integrated Products, Inc. ©  2018 Maxim Integrated Products, Inc. │  18